Abstract: The disclosure generally pertains to systems and methods for assigning alternative energy vehicles to travel routes based on vehicle wear-and-tear ratings. Wear-and-tear ratings may be influenced by factors such as, for example, road grade, travel speed, electric motor use, and battery use, on various travel routes. An example method for determining a wear-and-tear rating of an alternative energy vehicle may involve determining an amount of stress imposed upon an electric motor of an alternative energy vehicle due to a grade of a road on a travel route, and an amount of energy consumed from a battery of the alternative energy vehicle due to a speed of travel on the travel route. The wear-and-tear rating of the alternative energy vehicle may then be determined based on the amount of stress imposed upon the electric motor and/or the amount of energy consumed from the battery on the travel route.

Abstract: A vehicle includes an electrical port configured to transfer electricity between a vehicle battery and a charge station, the port including indicia viewable by operators of the port. The vehicle includes a controller configured to operate the indicia to flicker at a frequency that is proportional to a throughput level of a charge. The operation is responsive to receiving the charge.

Abstract: A method is provided for estimating range per full charge (RPC) for a vehicle. The method includes a controller which may, in response to detecting presence of a predefined condition impacting vehicle energy consumption, output to an interface by a controller a RPC and indicia indicative of an extent to which the predefined condition is affecting the RPC. An electrified vehicle including one or more vehicle components, a traction battery to supply energy to the vehicle components, one or more sensors, and a controller is also provided. The one or more sensors monitor the vehicle components, traction battery, and preselected ambient conditions. The controller is configured to, in response to input from the sensors, generate output for an interface which includes a RPC and indicia indicative of an extent of impact on the RPC by each of the ambient conditions and operation of the components and battery.

Abstract: A vehicle includes a display and a controller that operates the display. A first icon representing a reference energy consumption value based on a predetermined target energy consumption rate is displayed. A second icon representing a present energy consumption value is displayed. The icons are positioned relative to one another based on a difference between the reference energy consumption value and the present energy consumption value. A numerical scale may be displayed having values associated with the first and second icons. A vehicle having a hybrid powertrain including a traction battery may display an effective electric distance traveled that is based on a ratio of power supplied by the traction battery to total power supplied by the powertrain.

Abstract: A method is provided for estimating range per full charge (RPC) for a vehicle. The method includes a controller which may, in response to detecting presence of a predefined condition impacting vehicle energy consumption, output to an interface by a controller a RPC and indicia indicative of an extent to which the predefined condition is affecting the RPC. An electrified vehicle including one or more vehicle components, a traction battery to supply energy to the vehicle components, one or more sensors, and a controller is also provided. The one or more sensors monitor the vehicle components, traction battery, and preselected ambient conditions. The controller is configured to, in response to input from the sensors, generate output for an interface which includes a RPC and indicia indicative of an extent of impact on the RPC by each of the ambient conditions and operation of the components and battery.

Abstract: A vehicle includes a display and a controller that operates the display. A first icon representing a reference energy consumption value based on a predetermined target energy consumption rate is displayed. A second icon representing a present energy consumption value is displayed. The icons are positioned relative to one another based on a difference between the reference energy consumption value and the present energy consumption value. A numerical scale may be displayed having values associated with the first and second icons. A vehicle having a hybrid powertrain including a traction battery may display an effective electric distance traveled that is based on a ratio of power supplied by the traction battery to total power supplied by the powertrain.

Abstract: One or more embodiments may include a method for remotely obtaining information about an energy source of a vehicle. Information identifying one or more vehicles and one or more drivers of the vehicles may be received at one or more computing devices remote from a vehicle. Instructions from the one or more remote computing devices may be transmitted requesting information from the identified vehicle(s) about a status of an energy source for the identified vehicle(s). The status information may be received at the remote computing device(s). Based on the energy source status information and the driver identifying information, a vehicle energy source status with respect to one or more attributes of the vehicle drivers may be calculated. Additionally, the vehicle energy source status may be displayed at the one or more devices.

Abstract: One or more embodiments may include a method for remotely obtaining information about an energy source of a vehicle. Information identifying one or more vehicles and one or more drivers of the vehicles may be received at one or more computing devices remote from a vehicle. Instructions from the one or more remote computing devices may be transmitted requesting information from the identified vehicle(s) about a status of an energy source for the identified vehicle(s). The status information may be received at the remote computing device(s). Based on the energy source status information and the driver identifying information, a vehicle energy source status with respect to one or more attributes of the vehicle drivers may be calculated. Additionally, the vehicle energy source status may be displayed at the one or more devices.

Abstract: A wind and solar power plant, producing electrical energy at any scale, site, and level above the ground, and with almost no wind, comprises rotor trains, mounted on decks of a garage-like building, each rotor train having a plurality of rotors positioned between a shroud and a wind tunnel. The wind is accelerated in a low middle part of the wind tunnel while flows from a high entrance towards a higher and wider exit. The blades of the rotors protrude into the middle part of the wind tunnel causing fast rotation of the rotors around horizontal axes. A super-diffuser, a booster and a wind tunnel are increasing the power of the wind and rotors in hundreds of times. Each rotor train comprises up to six rotors connected with twelve electrical generators. Electrical energy can be also produced by solar panels, mounted on the balconies and on the roof of the building.

Abstract: A wind and solar power plant, producing electrical energy at any scale, site, and level above the ground, and with almost no wind, comprises rotor trains, mounted on decks of a garage-like building, each rotor train having a plurality of rotors positioned between a shroud and a wind tunnel. The wind is accelerated in a low middle part of the wind tunnel while flows from a high entrance towards a higher and wider exit. The blades of the rotors protrude into the middle part of the wind tunnel causing fast rotation of the rotors around horizontal axes. A super-diffuser, a booster and a wind tunnel are increasing the power of the wind and rotors in hundreds of times. Each rotor train comprises up to six rotors connected with twelve electrical generators. Electrical energy can be also produced by solar panels, mounted on the balconies and on the roof of the building.

Abstract: A wind power plant for producing electrical energy on a large scale, comprising a base, a housing, rotatable on said base around vertical axis. A wind tail, attached to the housing, rotate the housing toward direction of the wind, utilizing the power of the wind, and produces additional tunnel suction to the flow of the wind from front side to back side of the housing. A plurality of turbines, equipped with rotors with wide blades, is mounted inside the housing one above another. Deflectors cover from the wind the front side of the rotors above their axis of rotation while computer controlled governors are covering the remaining front side of the rotors below their axis of rotation, keeping steady the speed of rotation of the rotors. Working surfaces of turbines are covered from heavy snow and during the storm and protected from birds. Power plant saves the area of occupied land, utilizing higher speed of wind on higher elevations.

Abstract: A wind power plant for producing electrical energy on a large scale, comprising a base, a housing, rotatable on said base around vertical axis. A wind tail, attached to the housing, rotate the housing toward direction of the wind, utilizing the power of the wind, and produces additional tunnel suction to the flow of the wind from front side to back side of the housing. A plurality of turbines, equipped with rotors with wide blades, is mounted inside the housing one above another. Deflectors cover from the wind the front side of the rotors above their axis of rotation while computer controlled governors are covering the remaining front side of the rotors below their axis of rotation, keeping steady the speed of rotation of the rotors. Working surfaces of turbines are covered from heavy snow and during the storm and protected from birds. Power plant saves the area of occupied land, utilizing higher speed of wind on higher elevations.